JP2008220095A - Coil insulator of rotating electrical machine - Google Patents

Coil insulator of rotating electrical machine Download PDF

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JP2008220095A
JP2008220095A JP2007056181A JP2007056181A JP2008220095A JP 2008220095 A JP2008220095 A JP 2008220095A JP 2007056181 A JP2007056181 A JP 2007056181A JP 2007056181 A JP2007056181 A JP 2007056181A JP 2008220095 A JP2008220095 A JP 2008220095A
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mica
insulation
boron nitride
slot
woven fabric
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JP4922018B2 (en
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Hiroshi Hatano
Susumu Nagano
Shinobu Sekido
Hiroyoshi Tsuchiya
Toshimitsu Yamada
Katsuhiko Yoshida
勝彦 吉田
寛芳 土屋
利光 山田
浩 幡野
進 長野
忍 関戸
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Toshiba Corp
株式会社東芝
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    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02KDYNAMO-ELECTRIC MACHINES
    • H02K3/00Details of windings
    • H02K3/32Windings characterised by the shape, form or construction of the insulation
    • H02K3/40Windings characterised by the shape, form or construction of the insulation for high voltage, e.g. affording protection against corona discharges

Abstract

<P>PROBLEM TO BE SOLVED: To provide a coil insulator of a rotating electrical machine which can improve thermal conductivity much more even if it is located and arranged edgewise of an insulating layer for securing an electric characteristic. <P>SOLUTION: Wires are bundled into wire flux. The coil insulator is arranged in a slot having a plurality of wire fluxes in a rotator core or a stator core of the rotating electrical machine. Isolation between the wires and main isolation surrounding wire flux with respect to the slot are performed. The coil insulator is provided with a mica layer consisting of at least a peeling mica or a laminated mica, fabric consisting of an inorganic substance or an organic substance, powder of hexagonal boron nitride whose crystallization index is 1.8 or above and thermosetting polymeric organic resin integrating the mica layer and powder of hexagonal boron nitride. Powder of hexagonal boron nitride is located and arranged in a coil longitudinal direction. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

本発明は、結晶化指数1.8以上の六方晶窒化ホウ素粉体を、コイル長手方向あるいはマイカテープ積層方向に対して沿層方向に配向して絶縁中に配置した回転電機のコイル絶縁物に関する。   The present invention relates to a coil insulator for a rotating electrical machine in which hexagonal boron nitride powder having a crystallization index of 1.8 or more is oriented in the direction of layering with respect to the coil longitudinal direction or the mica tape laminating direction and arranged in the insulation. .
大型あるいは高電圧回転電機のコイルには、マイカと熱硬化性の高分子有機樹脂を主成分とした絶縁が適用されるケースが多い。しかし、金属やセラミックに比較して耐熱性に劣る有機樹脂を絶縁の主構成材料の一つとして使用しており、機器の運転中、ジュール損によるコイル温度の上昇によって劣化作用を受ける。このため、回転電機、特に大型の発電機ではさまざまなコイル冷却方式を採用し、劣化作用を抑制している。  In many cases, insulation of mica and thermosetting polymer organic resin as main components is applied to a coil of a large or high voltage rotating electrical machine. However, an organic resin that is inferior in heat resistance as compared with metals and ceramics is used as one of the main constituent materials of insulation, and during operation of the device, it is deteriorated by an increase in coil temperature due to Joule loss. For this reason, various coil cooling systems are employed in rotating electrical machines, particularly large generators, to suppress the deterioration effect.
この冷却方式は、導体を中空構造にし、水あるいは水素を循環させてコイルを直接冷却する直接冷却方式と、コイル導体に発生したジュール熱をコイル絶縁を経由して鉄心に放熱して冷却するか、鉄心内部を循環する水素あるいは空気によって冷却する間接冷却方式の2種類に大別される。   In this cooling method, the conductor is made into a hollow structure and water or hydrogen is circulated to directly cool the coil, and the Joule heat generated in the coil conductor is radiated to the iron core via the coil insulation for cooling. These are roughly classified into two types, indirect cooling systems that are cooled by hydrogen or air circulating inside the iron core.
最近では、その構造がシンプルでメンテナンス性に優れ、かつ低価格な間接冷却方式が注目され、かつその大容量化が進んでいる。   Recently, an indirect cooling method that is simple in structure, excellent in maintainability, and low in price has attracted attention, and its capacity has been increasing.
しかし、間接冷却方式はコイル絶縁を経由してジュール熱を放熱するため、金属やセラミックに比較して熱伝導性に劣る絶縁によって放熱が妨げられ、直接冷却方式に比較して冷却能力が劣る場合が多い。そのため、一例として以下に記述するような絶縁の熱伝導性を改善する手法が、特許文献1に開示されている。   However, indirect cooling method dissipates Joule heat via coil insulation, so heat dissipation is hindered by insulation that is inferior in thermal conductivity compared to metal or ceramic, and cooling capacity is inferior compared to direct cooling method There are many. Therefore, Patent Document 1 discloses a technique for improving the thermal conductivity of insulation as described below as an example.
図6および図7は、これを説明するための図である。互いに隣接して配列され、しかも導線相互間の絶縁のための導線絶縁19、ならびに機器のスロットに対する導線束を取り巻く主絶縁20を施した多数の導線21の束22を含んで成り、該主絶縁は導線束の周囲を数層をなして巻いてあり、かつ小さなマイカフレーク(剥がしマイカ)23を有する層24を含んで成るテープ形状またはシート形状の絶縁材料の包装材を含んで成り、該マイカフレーク層24、ならびに包装材中の該マイカフレーク層24間の空間25は硬化された含浸樹脂を含有するものである。   6 and 7 are diagrams for explaining this. A wire insulation 19 for insulation between the conductors arranged adjacent to each other, and a bundle 22 of a number of conductors 21 with a main insulation 20 surrounding the wire bundle for the slot of the device, the main insulation Comprises a packaging material of an insulating material in the form of a tape or sheet comprising a layer 24 having small mica flakes (peeled mica) 23 wound around the conductor bundle in several layers. The space 25 between the flake layer 24 and the mica flake layer 24 in the packaging material contains a cured impregnating resin.
回転電機の固定子または回転子におけるスロット内に配列するためのコイル、特に高電圧コイルにおいて少なくともマイカ層間の空間25に配置される含浸樹脂の部分が少なくとも5W/mKの固有熱伝導度と充填材の少なくとも90重量%において、0.1〜15μmの粒子の粒径とを有する充填材の粒子26を含有することを特徴としている。   Intrinsic thermal conductivity and filler of at least 5 W / mK of impregnated resin disposed in a space 25 between at least mica layers in a stator for a rotating electrical machine or a coil for arranging in a slot in a rotor, particularly a high voltage coil And at least 90% by weight of filler particles 26 having a particle size of 0.1 to 15 μm.
ここで、5W/mK以上の熱伝導率を有する充填材に六方晶窒化ホウ素の粉体を用いる場合、当該物質は熱伝導性に異方性があり、結晶軸のZ軸方向の熱伝導率が低いので、熱伝導性改善の観点からは、前記マイカフレーク層24の積層方向と結晶のZ軸が垂直、つまり、マイカフレーク層24の積層方向に対して貫層方向に配向して配置されることがより望ましい。   Here, when a hexagonal boron nitride powder is used as a filler having a thermal conductivity of 5 W / mK or more, the substance has anisotropy in thermal conductivity, and the thermal conductivity in the Z-axis direction of the crystal axis. From the viewpoint of improving thermal conductivity, the stacking direction of the mica flake layer 24 and the Z axis of the crystal are perpendicular to each other, that is, the mica flake layer 24 is oriented in the through layer direction. It is more desirable.
一方、当該物質は鱗片状であるため、電気的には課電劣化の原因である電気トリーの進展経路長が延長するように、マイカフレーク層24の積層方向と結晶のZ軸が平行、つまり、マイカフレーク層24の積層方向あるいはコイル長手方向に対して沿層方向に配向して配置されることが望ましく、電気的特性と熱伝導性を両立することが困難であった。   On the other hand, since the substance is scaly, the stacking direction of the mica flake layer 24 is parallel to the Z axis of the crystal so that the path length of the electrical tree that causes electrical degradation is electrically extended. It is desirable that the mica flake layer 24 is arranged in the layering direction with respect to the stacking direction of the mica flake layer 24 or the coil longitudinal direction, and it is difficult to achieve both electrical characteristics and thermal conductivity.
特許文献2には、粒径30〜100μmの窒化ホウ素粉体をマイカシート中に配合し、エポキシ樹脂積層品とした時の熱伝導率が、未配合品に比較して熱伝導率が向上したと記載されている。しかしながら、上記粉体の粒径を明細書記載の粒径厚さ1〜50μm、大きさ0.1〜1.5mmのマイカと共に抄造しマイカシートとすると、マイカシート中のマイカ鱗片と同じ方向に配向して、コイル絶縁とした時に、マイカシート積層方向あるいはコイル長手方向の沿層方向に配向して六方晶窒化ホウ素粉体が配置されるので、窒化ホウ素の熱伝導率がより低い方向で用いることになる。この場合には、未配合品に比較して電気特性、熱伝導性共に改善がみられるが、熱伝導性をより改善する余地もある。
特開昭63−110929号公報 特開昭55−53802号公報
In Patent Document 2, the thermal conductivity when a boron nitride powder having a particle size of 30 to 100 μm is blended in a mica sheet to form an epoxy resin laminated product is improved as compared with an unblended product. It is described. However, when the particle size of the powder is made together with mica having a particle size thickness of 1 to 50 μm and a size of 0.1 to 1.5 mm as described in the specification, a mica sheet is formed in the same direction as the mica scale in the mica sheet. When oriented to provide coil insulation, hexagonal boron nitride powder is oriented in the mica sheet laminating direction or the longitudinal direction of the coil, so that it is used in the direction where the thermal conductivity of boron nitride is lower. It will be. In this case, both electrical characteristics and thermal conductivity are improved as compared with the unblended product, but there is room for further improvement in thermal conductivity.
Japanese Unexamined Patent Publication No. 63-110929 JP-A-55-53802
特許文献1の例では、高熱伝導な材料を充填することにより熱伝導性は向上するものの、熱伝導性に異方性がありかつ鱗片状の材料である六方晶窒化ホウ素を充填する場合には、熱伝導率の改善の程度が配向によって抑制されることがある。   In the example of Patent Document 1, although the thermal conductivity is improved by filling a material having a high thermal conductivity, the hexagonal boron nitride, which is anisotropic and has a scale-like material, is filled. The degree of improvement in thermal conductivity may be suppressed by orientation.
特に、回転電機のコイル絶縁物絶縁に使われる場合には、電気的特性の観点から、熱伝導率が小さくなるように配向させると都合が良いため、この傾向が顕著に現われる。また、高熱伝導マイカテープ製造の観点からも、マイカテープ表面に刷毛やバーコーターによって塗布したり、滴下によって塗布するので、配向しやすい。   In particular, when used for coil insulator insulation of a rotating electrical machine, it is convenient to orient so that the thermal conductivity is small from the viewpoint of electrical characteristics, and this tendency appears remarkably. In addition, from the viewpoint of manufacturing a high thermal conductivity mica tape, it is easy to orient because it is applied to the surface of the mica tape by a brush or a bar coater or by dropping.
特許文献2の例では、鱗片形状を有するマイカ片と共に同じく鱗片形状を有する六方晶窒化ホウ素を抄紙するため、特許文献1の例に比較してより一層配向し、熱伝導率の改善が抑制される傾向にある。   In the example of Patent Document 2, since hexagonal boron nitride having the same scaly shape is made together with the mica piece having the scaly shape, the paper is oriented more than the example of Patent Document 1, and the improvement of the thermal conductivity is suppressed. Tend to.
このように、結晶構造や熱伝導性に異方性を有する六方晶窒化ホウ素を用いた回転電機絶縁においては、配向によって熱伝導性の改善が阻害される例がある。よって、電気的特性を確保するために配向させ、かつ熱伝導性も大きく改善することのできる回転電機絶縁が望まれていた。   Thus, in rotating electrical machine insulation using hexagonal boron nitride having anisotropy in crystal structure and thermal conductivity, there is an example in which improvement in thermal conductivity is hindered by orientation. Therefore, there has been a demand for a rotating electrical machine insulation that can be oriented to ensure electrical characteristics and that can greatly improve thermal conductivity.
本発明はこのような事情に基づいてなされたもので、六方晶窒化ホウ素の粉末をコイル絶縁として使用しているものにおいて、電気的特性を確保しつつ熱伝導性をさらに改善した回転電機のコイル絶縁物を提供することを目的とする。   The present invention has been made based on such circumstances, and uses a hexagonal boron nitride powder as coil insulation, and the coil of a rotating electrical machine further improves thermal conductivity while ensuring electrical characteristics. The object is to provide an insulator.
前記目的を達成するため、請求項1に対応する発明は、導線を束ねて導線束を構成し、該導線束を回転電機の回転子鉄心又は固定子鉄心に有するスロット内に配設され、前記導線相互間の絶縁並びに前記スロットに対する導線束を取り巻く主絶縁を施こすためのものであって、剥がしマイカあるいは集成マイカの少なくとも一つから構成されるマイカ層と、無機物あるいは有機物の少なくともいずれか一つからなる織布と、結晶化指数が1.8以上の六方晶窒化ホウ素の粉体と、前記マイカ層と六方晶窒化ホウ素の粉体を一体化せしめる熱硬化性の高分子有機樹脂とからなり、前記六方晶窒化ホウ素の粉体がコイル長手方向に配向して配置されるようにした回転電機のコイル絶縁物である。   In order to achieve the above object, the invention corresponding to claim 1 is configured to bundle a conducting wire to form a conducting wire bundle, and the conducting wire bundle is disposed in a slot having a rotor core or a stator core of a rotating electrical machine, In order to provide insulation between conductors and main insulation surrounding the wire bundle with respect to the slot, a mica layer composed of at least one of peeled mica or laminated mica, and at least one of an inorganic substance and an organic substance A hexagonal boron nitride powder having a crystallization index of 1.8 or more, and a thermosetting polymer organic resin in which the mica layer and the hexagonal boron nitride powder are integrated. The coil insulator of a rotating electrical machine is configured such that the hexagonal boron nitride powder is oriented in the longitudinal direction of the coil.
前記目的を達成するため、請求項2に対応する発明は、絶縁被覆導線を束ねて導線束を構成し、該導線束を回転電機の回転子鉄心又は固定子鉄心に有するスロット内に配設され、前記導線相互間の絶縁並びに前記スロットに対する導線束を取り巻く主絶縁を施こすためのものであって、剥がしマイカあるいは集成マイカの少なくとも一つから構成されるマイカ層と、無機物あるいは有機物の少なくともいずれか一つからなる織布と、前記マイカ層と織布を接着する高分子有機樹脂からなるマイカテープを構成し、前記マイカテープの織布の対向面あるいは前記マイカ層の対向面の少なくとも一方に、結晶化指数が1.8以上の六方晶窒化ホウ素の粉体を含む有機樹脂を塗布した樹脂塗布マイカテープを、前記導線束に巻回した後、該マイカテープに熱硬化性の高分子有機樹脂を含浸し、且つ硬化して得られる回転電機のコイル絶縁物である。   In order to achieve the above object, the invention corresponding to claim 2 forms an electric wire bundle by bundling insulation-coated electric wires, and the electric wire bundle is disposed in a slot having a rotor core or a stator core of a rotating electric machine. , For providing insulation between the conductors and main insulation surrounding the conductor bundle for the slot, and a mica layer composed of at least one of peeled mica or laminated mica, and at least one of an inorganic substance and an organic substance And a mica tape made of a polymer organic resin that adheres the mica layer and the woven fabric. At least one of the facing surface of the woven fabric of the mica tape or the facing surface of the mica layer is formed. After winding a resin-coated mica tape coated with an organic resin containing hexagonal boron nitride powder having a crystallization index of 1.8 or more around the wire bundle, A thermosetting polymer organic resin is impregnated into flop a and the coil insulator of the rotary electric machine obtained by curing.
前記目的を達成するため、請求項3に対応する発明は、絶縁被覆導線を束ねて導線束を構成し、該導線束を回転電機の回転子鉄心又は固定子鉄心に有するスロット内に配設され、前記導線相互間の絶縁並びに前記スロットに対する導線束を取り巻く主絶縁を施こすためのものであって、結晶化指数が1.8以上の六方晶窒化ホウ素の粉体を混抄、抄造した集成マイカペーパと、無機物あるいは有機物の少なくともいずれか一つからなる織布と、前記集成マイカペーパと織布を接着する高分子有機樹脂からなるマイカテープを、前記導線束に巻回した後、該マイカテープに熱硬化性の高分子有機樹脂を含浸し、且つ硬化して得られる回転電機のコイル絶縁物である。   In order to achieve the above object, an invention corresponding to claim 3 is configured such that a wire bundle is formed by bundling insulating coated conductors, and the conductor bundle is disposed in a slot having a rotor core or a stator core of a rotating electrical machine. In order to provide insulation between the conductors and main insulation surrounding the bundle of conductors with respect to the slots, a composite mica paper obtained by mixing and papering hexagonal boron nitride powder having a crystallization index of 1.8 or more And a woven fabric made of at least one of an inorganic material and an organic material, and a mica tape made of a polymer organic resin that adheres the laminated mica paper and the woven fabric, is wound around the wire bundle, and then the mica tape is heated. A coil insulator for a rotating electrical machine obtained by impregnating and curing a curable polymer organic resin.
前記目的を達成するため、請求項4に対応する発明は、絶縁被覆導線を束ねて導線束を構成し、該導線束を回転電機の回転子鉄心又は固定子鉄心に有するスロット内に配設され、前記導線相互間の絶縁並びに前記スロットに対する導線束を取り巻く主絶縁を施こすためのものであって、剥がしマイカあるいは集成マイカの少なくとも一つから構成されるマイカ層と、無機物あるいは有機物の少なくともいずれか一つからなる織布と、前記マイカ層と織布を接着する半硬化した熱硬化性の高分子有機樹脂からなるマイカテープを、前記織布と対向する面あるいはマイカ層と対向する面の少なくとも一方に、少なくとも結晶化指数が1.8以上の六方晶窒化ホウ素の粉体を含む有機樹脂で塗布したマイカテープで、前記導線束に巻回した後、加圧成形し、かつ加熱硬化して得られる回転電機のコイル絶縁物である。   In order to achieve the above object, the invention corresponding to claim 4 forms an electric wire bundle by bundling insulation-coated electric wires, and the electric wire bundle is disposed in a slot having a rotor core or a stator iron core of a rotating electric machine. , For providing insulation between the conductors and main insulation surrounding the conductor bundle for the slot, and a mica layer composed of at least one of peeled mica or laminated mica, and at least one of an inorganic substance and an organic substance And a mica tape made of a semi-cured thermosetting polymer organic resin for bonding the mica layer and the woven fabric to a surface facing the woven fabric or a surface facing the mica layer. At least one of the mica tapes coated with an organic resin containing hexagonal boron nitride powder having a crystallization index of 1.8 or more is wound around the wire bundle and then pressed. And shape, and a coil insulator of the rotary electric machine obtained by heat-curing.
前記目的を達成するため、請求項5に対応する発明は、絶縁被覆導線を束ねて導線束を構成し、該導線束を回転電機の回転子鉄心又は固定子鉄心に有するスロット内に配設され、前記導線相互間の絶縁並びに前記スロットに対する導線束を取り巻く主絶縁を施こすためのものであって、結晶化指数が1.8以上の六方晶窒化ホウ素の粉体を混抄、抄造した集成マイカと、無機物あるいは有機物の少なくともいずれか一つからなる織布と、前記集成マイカと織布を接着する半硬化した熱硬化性の高分子有機樹脂からなるマイカテープを、前記導線束に巻回した後、加圧成形・加熱硬化して得られる回転電機のコイル絶縁物である。   In order to achieve the above object, an invention corresponding to claim 5 is configured such that a wire bundle is formed by bundling insulating coated conductors, and the conductor bundle is disposed in a slot having a rotor core or a stator core of a rotating electrical machine. In order to provide insulation between the conductors and main insulation surrounding the bundle of conductors with respect to the slots, a composite mica obtained by mixing and making a hexagonal boron nitride powder having a crystallization index of 1.8 or more And a woven fabric made of at least one of an inorganic material and an organic material, and a mica tape made of a semi-cured thermosetting polymer organic resin for bonding the laminated mica and the woven fabric was wound around the wire bundle. It is a coil insulator for a rotating electrical machine obtained by subsequent pressure molding and heat curing.
本発明に係る回転電機のコイル絶縁物は、六方晶窒化ホウ素の粉体の結晶化指数を1.8以上とすることにより、電気的特性を確保するために絶縁層の沿層方向に配向して配置させても、熱伝導性をより向上させることができる。   The coil insulator of the rotating electrical machine according to the present invention is oriented in the creeping direction of the insulating layer in order to ensure electrical characteristics by setting the crystallization index of the hexagonal boron nitride powder to 1.8 or more. Even if it arrange | positions, thermal conductivity can be improved more.
以下、本発明の実施形態について、図1〜図5及び表1、表2を参照して説明する。本発明の回転電機のコイル絶縁物は、導線を束ねて導線束を構成し、該導線束を複数個回転電機の回転子鉄心又は固定子鉄心に有するスロット内に配設され、前記導線相互間の絶縁並びに前記スロットに対する導線束を取り巻く主絶縁を施こすためのものであって、剥がしマイカあるいは集成マイカの少なくとも一つから構成されるマイカ層と、無機物あるいは有機物の少なくともいずれか一つからなる織布と、結晶化指数が1.8以上の六方晶窒化ホウ素の粉体と、前記マイカ層と六方晶窒化ホウ素の粉体を一体化せしめる熱硬化性の高分子有機樹脂とからなり、前記六方晶窒化ホウ素の粉体がコイル長手方向に配向して配置されるようにしたものであり、これについて具体的に説明する。   Embodiments of the present invention will be described below with reference to FIGS. 1 to 5 and Tables 1 and 2. The coil insulator of the rotating electrical machine of the present invention comprises a bundle of conducting wires to form a conducting wire bundle, and is disposed in a slot having a plurality of the conducting wire bundles in a rotor core or a stator core of the rotating electrical machine. And a main insulation surrounding the bundle of conductors for the slot, comprising a mica layer composed of at least one of peeled mica or laminated mica, and at least one of an inorganic substance or an organic substance. A woven fabric, a hexagonal boron nitride powder having a crystallization index of 1.8 or more, and a thermosetting polymer organic resin that integrates the mica layer and the hexagonal boron nitride powder, The hexagonal boron nitride powder is arranged in the longitudinal direction of the coil and will be described in detail.
ここで、結晶化指数(GI:graphtization index)とは、X線回折像において、窒化ホウ素の(100)面、(101)面、(102)面のピーク面積を用いて(2)式で表される値のことである。   Here, the crystallization index (GI) is expressed by equation (2) using the peak areas of the (100) plane, (101) plane, and (102) plane of boron nitride in an X-ray diffraction image. It is a value to be set.
GI=(S(100)+S(101))/S(102) …(2)式
ここで、S(100)は(100)面のピーク面積を示す。
GI = (S (100) + S (101)) / S (102) (2) formula
Here, S (100) represents the peak area of the (100) plane.
図1は、本発明に使用する高熱伝導性のマイカテープを説明するための図である。マイカテープは、マスコバイトを素材とした硬質無焼成集成マイカペーパ1とガラスクロス2に、エピコート1001およびエピコート828(油化シェルエポキシ製)を重量比で10対90になるように配合され、なおかつ溶剤のメチルエチルケトンで希釈されたエポキシ樹脂接着剤3を含浸、この溶剤を乾燥・揮発させてマイカテープ4を製造される。   FIG. 1 is a view for explaining a high thermal conductivity mica tape used in the present invention. Mica tape is blended with hard unfired laminated mica paper 1 and glass cloth 2 made of mascobite so that Epicoat 1001 and Epicoat 828 (made of oiled shell epoxy) have a weight ratio of 10:90, and a solvent. The mica tape 4 is manufactured by impregnating the epoxy resin adhesive 3 diluted with methyl ethyl ketone and drying and volatilizing the solvent.
そしてさらに、同じ配合のエポキシ樹脂接着剤3中に表1の比較例1の欄に示す性状の六方晶窒化ホウ素の粉体5を配合、前記マイカテープ4のガラスクロス2の面に塗布、同様に溶剤を再度揮発・乾燥して粉体層6を形成し、高熱伝導マイカテープ7を得る。なお、塗布時には、六方晶窒化ホウ素粉末5が、マイカシートやガラスクロスの積層方向に対して沿層方向に配向するように配慮した。   Furthermore, the hexagonal boron nitride powder 5 having the properties shown in the column of Comparative Example 1 in Table 1 is blended in the epoxy resin adhesive 3 having the same composition, and applied to the surface of the glass cloth 2 of the mica tape 4. Then, the solvent is volatilized and dried again to form a powder layer 6 to obtain a high thermal conductivity mica tape 7. At the time of application, consideration was given so that the hexagonal boron nitride powder 5 was oriented in the layering direction with respect to the lamination direction of the mica sheet or glass cloth.
この高熱伝導マイカテープの詳細仕様は、表2に示すように、マイカ重量160(g/m)、ガラスクロス重量25(g/m)、ガラスクロス厚さ0.030(mm)、接着剤重量25(g/m)、六方晶窒化ホウ素重量55(g/m)、マイカテープ重量265(g/m)、マイカテープ幅30(mm)、マイカテープ厚さ0.20(mm)である。 As shown in Table 2, the detailed specifications of the high thermal conductivity mica tape are as follows: mica weight 160 (g / m 2 ), glass cloth weight 25 (g / m 2 ), glass cloth thickness 0.030 (mm), adhesion Agent weight 25 (g / m 2 ), hexagonal boron nitride weight 55 (g / m 2 ), mica tape weight 265 (g / m 2 ), mica tape width 30 (mm), mica tape thickness 0.20 ( mm).
このようにして得られた高熱伝導マイカテープ7を、回転電機のコイル導体を模擬したアルミニウム製のバー8(10×50×1000mm)へ、図2に示すように当該テープがテープ幅の1/2分だけ重なるようにして10回、テープ層数で20層になるように巻回し、エポキシ樹脂組成物(TVB2632、東芝ケミカル製)を真空加圧含浸した。真空引きの条件は13.3Paで10時間、加圧は0.5MPaで15時間である。この後、加熱硬化後の絶縁層9の厚さが3.5mmになるよう、上下左右の4面に離型処理をしたステンレス板10を図3に示すように当てて、圧縮しながら加熱硬化し、ステンレス板10を除去して回転電機の例えば電機子の絶縁コイル11を得た。加熱は熱風循環式恒温槽にて150℃、20時間で実施した。
The high thermal conductivity mica tape 7 thus obtained is applied to an aluminum bar 8 (10 × 50 × 1000 mm) simulating a coil conductor of a rotating electric machine, as shown in FIG. The film was wound 10 times so as to overlap for 2 minutes and 20 tape layers, and impregnated with an epoxy resin composition (TVB2632, manufactured by Toshiba Chemical) under vacuum and pressure. The vacuuming condition is 13.3 Pa for 10 hours, and the pressure is 0.5 MPa for 15 hours. Thereafter, the stainless steel plate 10 subjected to the release treatment is applied to the upper, lower, left and right four surfaces so that the thickness of the insulating layer 9 after the heat curing becomes 3.5 mm as shown in FIG. Then, the stainless steel plate 10 was removed to obtain an insulating coil 11 of, for example, an armature of the rotating electric machine. Heating was performed at 150 ° C. for 20 hours in a hot air circulating thermostat.
なお、表1において、平均粒径はレーザ回折法により測定した値であり、比表面積はBET法により測定した値であり、結晶化指数はX線回折像から求めた値であり、熱伝導率はASTM D4351により測定した値である。   In Table 1, the average particle diameter is a value measured by the laser diffraction method, the specific surface area is a value measured by the BET method, the crystallization index is a value obtained from an X-ray diffraction image, and the thermal conductivity. Is a value measured by ASTM D4351.
比較例2は、比較例1のように六方晶窒化ホウ素の粉末の結晶化指数を0.9とせずに、1.4とした場合であり、この場合比較例1の熱伝導率は、0.41W/mKであり、また比較例2の熱伝導率は、0.43W/mKである。   Comparative Example 2 is a case where the crystallization index of the hexagonal boron nitride powder is set to 1.4 instead of 0.9 as in Comparative Example 1, and in this case, the thermal conductivity of Comparative Example 1 is 0. .41 W / mK, and the thermal conductivity of Comparative Example 2 is 0.43 W / mK.
これに対して本発明の実施例1における六方晶窒化ホウ素の粉末の結晶化指数を2.0とし、実施例2は3.0としたものであり、実施例1の熱伝導率は、0.49W/mKであり、実施例2の熱伝導率は、0.60W/mKと、本発明の実施例1、2の方が比較例1、2に比べて熱伝導率が高いことがわかる。   On the other hand, the crystallization index of the hexagonal boron nitride powder in Example 1 of the present invention was 2.0, Example 2 was 3.0, and the thermal conductivity of Example 1 was 0. .49 W / mK, and the thermal conductivity of Example 2 is 0.60 W / mK, indicating that the thermal conductivity of Examples 1 and 2 of the present invention is higher than that of Comparative Examples 1 and 2. .
このようにして得られた回転電機電のコイルの絶縁層9の断面をそれぞれの例について観察したところ、マイカテープ層の沿層方向に配向していた。   When the cross section of the insulating layer 9 of the thus obtained rotating electrical machine coil was observed for each example, it was oriented in the creeping direction of the mica tape layer.
同じコイルの長手方向中央部の絶縁層9より、直径が35mm、厚さ3.5mmの円板をそれぞれ切り出し、マイカテープ層貫層方向について定常法による熱伝導率(ASTM D4351に準拠)を測定した。この結果、図4に示すように結晶化指数が高くなるほど熱伝導率が増大し、特に結晶化指数1.4から2.0の間で急激に増大する傾向を示すことから、結晶化指数は1.8以上であることが好ましい。   From the insulating layer 9 at the center in the longitudinal direction of the same coil, disks each having a diameter of 35 mm and a thickness of 3.5 mm are cut out, and the thermal conductivity (according to ASTM D4351) is measured in the mica tape layer penetration direction. did. As a result, as shown in FIG. 4, the higher the crystallization index, the higher the thermal conductivity, and in particular, the tendency to increase rapidly between crystallization index 1.4 to 2.0. It is preferable that it is 1.8 or more.
さらに、作製したぞれぞれのコイルについて、誘電正接の電圧依存性、絶縁破壊電圧、課電寿命を評価したところ、比較例1、2、実施例1、2のすべてが同等の結果を示した。   Furthermore, when the voltage dependence of dielectric loss tangent, dielectric breakdown voltage, and electrical charging life were evaluated for each of the produced coils, Comparative Examples 1 and 2 and Examples 1 and 2 all showed equivalent results. It was.
次に、比較例3と実施例3について説明する。比較例3は結晶化指数を0.9とし且つ一部の条件を次のようにしたものであり、また実施例3は2.0とし且つ一部の条件を次のようにしたものである。   Next, Comparative Example 3 and Example 3 will be described. In Comparative Example 3, the crystallization index was 0.9 and some conditions were as follows. In Example 3, 2.0 was set and some conditions were as follows. .
ここで使用した高熱伝導性マイカテープ12は、図5に示すように焼成集成マイカ13を100部、芳香族ポリアミドフィブリッド(漏水度60゜SR)14を40部および前記表1の比較例1欄に記載の六方晶窒化ホウ素15を20部混合した分散液を円網式抄紙機にて抄造して得られた厚さ0.08mmの硬質焼成集成マイカペーパー16と、ガラスクロス(厚さ0.030mm)17に、エピコート1001およびエピコート828(油化シェルエポキシ製)を重量比で10対90になるように配合され、なおかつ溶剤のメチルエチルケトンで希釈されたエポキシ樹脂接着剤18を含浸、この溶剤を乾燥・揮発させて製造される。   As shown in FIG. 5, the high thermal conductivity mica tape 12 used here was 100 parts of fired laminated mica 13 and 40 parts of aromatic polyamide fibrid (water leakage 60 ° SR) 14 and Comparative Example 1 in Table 1 above. A hard-fired laminated mica paper 16 having a thickness of 0.08 mm obtained by making a dispersion obtained by mixing 20 parts of the hexagonal boron nitride 15 described in the column with a circular paper machine, and a glass cloth (thickness 0) .030 mm) 17 is impregnated with an epoxy resin adhesive 18 in which Epicoat 1001 and Epicoat 828 (manufactured by oil-coated shell epoxy) are blended in a weight ratio of 10 to 90 and diluted with methyl ethyl ketone as a solvent. It is manufactured by drying and volatilizing.
このようにして得られた厚さ0.12mm、幅25mmの高熱伝導性マイカテープ12を用いて、回転電機のコイルを製造した。コイル製造方法はマイカテープ巻回数を15回とした以外は比較例1と同様である。   A coil of a rotating electrical machine was manufactured using the high thermal conductivity mica tape 12 having a thickness of 0.12 mm and a width of 25 mm obtained in this manner. The coil manufacturing method is the same as that of Comparative Example 1 except that the mica tape winding number is set to 15.
このようにして得られた比較例3および実施例3の回転電機電機子絶縁コイル絶縁層の断面について観察したところ、マイカペーパー中のマイカ鱗片と同じ方向に、つまりマイカテープ層の沿層方向に配向していることを確認した。   When the cross sections of the rotating armature armature insulation coil insulation layers of Comparative Example 3 and Example 3 obtained in this way were observed, they were in the same direction as the mica scales in the mica paper, that is, in the creeping direction of the mica tape layer. It was confirmed that it was oriented.
同じコイルの長手方向中央部の絶縁層より、直径が35mm、厚さ3.5mmの円板をそれぞれ切り出し、マイカテープ層貫層方向について定常法による熱伝導率(ASTM D4351に準拠)を測定した。この結果、比較例3の熱伝導率は0.40W/mK、実施例3の熱伝導率は0.47W/mKと、後者の熱伝導率が高いことを確認した。 A disc having a diameter of 35 mm and a thickness of 3.5 mm was cut out from the insulating layer at the central portion in the longitudinal direction of the same coil, and thermal conductivity (according to ASTM D4351) was measured in the mica tape layer penetration direction. . As a result, the thermal conductivity of Comparative Example 3 was 0.40 W / mK, and the thermal conductivity of Example 3 was 0.47 W / mK, confirming that the latter had high thermal conductivity.
以上述べた実施形態によれば、六方晶窒化ホウ素の粉体の結晶化指数を1.8以上とすることにより、電気的特性を確保するために絶縁層の沿層方向に配向して配置させても、熱伝導性をより向上させることができる。   According to the embodiment described above, by setting the crystallization index of the hexagonal boron nitride powder to 1.8 or more, the insulating layer is oriented and arranged in the creeping direction in order to ensure electrical characteristics. However, the thermal conductivity can be further improved.
本発明は、以上述べた実施形態以外に、次のようにしてもよい。   In addition to the embodiments described above, the present invention may be as follows.
例えば図6に示すように、絶縁被覆導線を束ねて導線束22を構成し、該導線束22を複数個回転電機の回転子鉄心又は固定子鉄心に有するスロット(図示しない)内に配設され、前記導線21相互間の絶縁並びに前記スロットに対する導線束を取り巻く主絶縁20を施こす場合に次のように行なえばよい。すなわち、剥がしマイカ(マイカフレーク)あるいは集成マイカの少なくとも一つから構成されるマイカ層と、無機物あるいは有機物の少なくともいずれか一つからなる織布例えばガラスクロスと、マイカ層と織布を接着する高分子有機樹脂からなるマイカテープを構成し、マイカテープの織布の対向面あるいは前記マイカ層の対向面の少なくとも一方に、結晶化指数が1.8以上の六方晶窒化ホウ素の粉体を含む有機樹脂を塗布した樹脂塗布マイカテープを、前記導線束に巻回した後、該マイカテープに熱硬化性の高分子有機樹脂を含浸し、且つ硬化して得るようにしてもよい。   For example, as shown in FIG. 6, a conductor bundle 22 is formed by bundling insulation-coated conductors, and a plurality of conductor bundles 22 are disposed in a slot (not shown) having a rotor core or stator core of a rotating electric machine. In the case of providing the insulation between the conductors 21 and the main insulation 20 surrounding the bundle of conductors with respect to the slots, the following may be performed. That is, a mica layer composed of at least one of peeled mica (mica flakes) or laminated mica, a woven fabric composed of at least one of inorganic and organic substances, such as glass cloth, An organic material comprising a mica tape made of a molecular organic resin, and containing a hexagonal boron nitride powder having a crystallization index of 1.8 or more on at least one of the facing surface of the woven fabric of the mica tape or the facing surface of the mica layer. The resin-coated mica tape coated with resin may be wound around the wire bundle, and then the mica tape may be impregnated with a thermosetting polymer organic resin and cured.
また、結晶化指数が1.8以上の六方晶窒化ホウ素の粉体を混抄、抄造した集成マイカペーパと、無機物あるいは有機物の少なくともいずれか一つからなる織布例えばガラスクロスと、集成マイカペーパと織布を接着する高分子有機樹脂からなるマイカテープを、導線束に巻回した後、該マイカテープに熱硬化性の高分子有機樹脂を含浸し、且つ硬化して得るようにしてもよい。   Also, a laminated mica paper obtained by mixing and making a hexagonal boron nitride powder having a crystallization index of 1.8 or more, a woven fabric made of at least one of inorganic and organic materials, for example, a glass cloth, and a laminated mica paper and woven fabric. Alternatively, a mica tape made of a polymer organic resin that adheres can be wound around a wire bundle, and then the mica tape is impregnated with a thermosetting polymer organic resin and cured.
さらに、剥がしマイカあるいは集成マイカの少なくとも一つから構成されるマイカ層と、無機物あるいは有機物の少なくともいずれか一つからなる織布例えばガラスクロスと、マイカ層と織布を接着する半硬化した熱硬化性の高分子有機樹脂からなるマイカテープを、織布と対向する面あるいはマイカ層と対向する面の少なくとも一方に、少なくとも結晶化指数が1.8以上の六方晶窒化ホウ素の粉体を含む有機樹脂で塗布したマイカテープで、導線束に巻回した後、加圧成形し、かつ加熱硬化して得るようにしてもよい。   Furthermore, a mica layer composed of at least one of peeled mica or laminated mica, a woven fabric composed of at least one of inorganic and organic materials, for example, a glass cloth, and a semi-cured thermosetting that bonds the mica layer and the woven fabric. Organic containing a hexagonal boron nitride powder having a crystallization index of at least 1.8 on at least one of the surface facing the woven fabric or the surface facing the mica layer A mica tape coated with a resin may be wound around a wire bundle, press-molded, and heat-cured.
また、結晶化指数が1.8以上の六方晶窒化ホウ素の粉体を混抄、抄造した集成マイカと、無機物あるいは有機物の少なくともいずれか一つからなる織布例えばガラスクロスと、集成マイカと織布を接着する半硬化した熱硬化性の高分子有機樹脂からなるマイカテープを、導線束に巻回した後、加圧成形・加熱硬化して得るようにしてもよい。   Also, a laminated mica obtained by mixing and making a hexagonal boron nitride powder having a crystallization index of 1.8 or more, a woven fabric made of at least one of an inorganic substance and an organic substance, for example, a glass cloth, a laminated mica and a woven cloth. Alternatively, a mica tape made of a semi-cured thermosetting polymer organic resin that adheres to may be obtained by winding it around a wire bundle, followed by pressure molding and heat curing.
本発明に係る回転電機のコイル絶縁物の実施形態における主構成部材である高熱伝導性マイカテープの断面図。Sectional drawing of the high thermal conductivity mica tape which is the main structural member in embodiment of the coil insulator of the rotary electric machine which concerns on this invention. 図1のマイカテープを導体に巻回した状態を示す部分断面図。FIG. 2 is a partial sectional view showing a state in which the mica tape of FIG. 1 is wound around a conductor. 図1に係る回転電機のコイル絶縁物を製造する場合における加熱硬化時の圧縮成形状況を表す模式図。The schematic diagram showing the compression molding situation at the time of heat-hardening in the case of manufacturing the coil insulator of the rotary electric machine which concerns on FIG. 本発明に係る回転電機のコイル絶縁物における、熱伝導率の結晶化指数依存性を示す特性図。The characteristic view which shows the crystallization index dependence of thermal conductivity in the coil insulator of the rotary electric machine which concerns on this invention. 本発明に係わる回転電機のコイル絶縁物の主構成部材である高熱伝導性マイカテープの断面図。Sectional drawing of the high thermal conductivity mica tape which is the main structural member of the coil insulator of the rotary electric machine concerning this invention. 従来の技術である回転電機の電機子コイルの断面図。Sectional drawing of the armature coil of the rotary electric machine which is a prior art. 図6のコイル絶縁物である、高熱伝導マイカテープを用いた電機子コイル絶縁の部分断面図。The fragmentary sectional view of the armature coil insulation using the high thermal conductivity mica tape which is the coil insulator of FIG.
符号の説明Explanation of symbols
1…硬質無焼成集成マイカペーパ、2…ガラスクロス、3…エポキシ樹脂接着剤、4…マイカテープ、5…六方晶窒化ホウ素の粉末、6…粉体層、7…高熱伝導マイカテープ、8…導体(導線)、9…絶縁層、10…ステンレス板、11…絶縁コイル、12…高熱伝導性マイカテープ、13…焼成集成マイカ、14…芳香族ポリアミドフィブリッド、15…六方晶窒化ホウ素、16…硬質焼成集成マイカペーパー、17…ガラスクロス、18…エポキシ樹脂接着剤、19…導線絶縁、20…主絶縁、21…導線、22…導線束、23…マイカフレーク、24…マイカフレーク層、25…空間、26…粒子。   DESCRIPTION OF SYMBOLS 1 ... Hard unbaked laminated mica paper, 2 ... Glass cloth, 3 ... Epoxy resin adhesive, 4 ... Mica tape, 5 ... Hexagonal boron nitride powder, 6 ... Powder layer, 7 ... High heat conductive mica tape, 8 ... Conductor (Conductive wire), 9 ... insulating layer, 10 ... stainless steel plate, 11 ... insulating coil, 12 ... high thermal conductivity mica tape, 13 ... fired laminated mica, 14 ... aromatic polyamide fibrid, 15 ... hexagonal boron nitride, 16 ... Hard fired laminated mica paper, 17 ... glass cloth, 18 ... epoxy resin adhesive, 19 ... conductor insulation, 20 ... main insulation, 21 ... conductor, 22 ... conductor bundle, 23 ... mica flake, 24 ... mica flake layer, 25 ... Space, 26 ... particles.

Claims (6)

  1. 導線を束ねて導線束を構成し、該導線束を回転電機の回転子鉄心又は固定子鉄心に有するスロット内に配設され、前記導線相互間の絶縁並びに前記スロットに対する導線束を取り巻く主絶縁を施こすためのものであって、
    剥がしマイカあるいは集成マイカの少なくとも一つから構成されるマイカ層と、無機物あるいは有機物の少なくともいずれか一つからなる織布と、結晶化指数が1.8以上の六方晶窒化ホウ素の粉体と、前記マイカ層と六方晶窒化ホウ素の粉体を一体化せしめる熱硬化性の高分子有機樹脂とからなり、前記六方晶窒化ホウ素の粉体がコイル長手方向に配向して配置されるようにした回転電機のコイル絶縁物。
    The conductor wires are bundled to form a conductor bundle, and the conductor bundle is disposed in a slot having the rotor core or the stator core of the rotating electric machine, and insulation between the conductors and main insulation surrounding the conductor bundle with respect to the slot are provided. For applying,
    A mica layer composed of at least one of peeled mica or laminated mica, a woven fabric composed of at least one of an inorganic substance and an organic substance, a hexagonal boron nitride powder having a crystallization index of 1.8 or more, A rotation made of a thermosetting polymer organic resin that integrates the mica layer and hexagonal boron nitride powder so that the hexagonal boron nitride powder is oriented in the longitudinal direction of the coil. Electric coil insulation.
  2. 絶縁被覆導線を束ねて導線束を構成し、該導線束を回転電機の回転子鉄心又は固定子鉄心に有するスロット内に配設され、前記導線相互間の絶縁並びに前記スロットに対する導線束を取り巻く主絶縁を施こすためのものであって、
    剥がしマイカあるいは集成マイカの少なくとも一つから構成されるマイカ層と、無機物あるいは有機物の少なくともいずれか一つからなる織布と、前記マイカ層と織布を接着する高分子有機樹脂からなるマイカテープを構成し、前記マイカテープの織布の対向面あるいは前記マイカ層の対向面の少なくとも一方に、結晶化指数が1.8以上の六方晶窒化ホウ素の粉体を含む有機樹脂を塗布した樹脂塗布マイカテープを、前記導線束に巻回した後、該マイカテープに熱硬化性の高分子有機樹脂を含浸し、且つ硬化して得られる回転電機のコイル絶縁物。
    A conductor bundle is formed by bundling insulation coated conductors, and the conductor bundle is disposed in a slot having the rotor core or stator core of the rotating electric machine, and the insulation between the conductors and the conductor bundle surrounding the slot For applying insulation,
    A mica layer composed of at least one of peeled mica or laminated mica, a woven fabric composed of at least one of an inorganic material and an organic material, and a mica tape composed of a polymer organic resin that adheres the mica layer and the woven fabric. A resin-coated mica in which an organic resin containing a hexagonal boron nitride powder having a crystallization index of 1.8 or more is applied to at least one of the opposing surface of the woven fabric of the mica tape or the opposing surface of the mica layer. A coil insulator for a rotating electrical machine obtained by winding a tape around the wire bundle and then impregnating and curing the mica tape with a thermosetting polymer organic resin.
  3. 絶縁被覆導線を束ねて導線束を構成し、該導線束を回転電機の回転子鉄心又は固定子鉄心に有するスロット内に配設され、前記導線相互間の絶縁並びに前記スロットに対する導線束を取り巻く主絶縁を施こすためのものであって、
    結晶化指数が1.8以上の六方晶窒化ホウ素の粉体を混抄、抄造した集成マイカペーパと、無機物あるいは有機物の少なくともいずれか一つからなる織布と、前記集成マイカペーパと織布を接着する高分子有機樹脂からなるマイカテープを、前記導線束に巻回した後、該マイカテープに熱硬化性の高分子有機樹脂を含浸し、且つ硬化して得られる回転電機のコイル絶縁物。
    A conductor bundle is formed by bundling insulation-coated conductors, and the conductor bundle is disposed in a slot having the rotor core or stator core of the rotating electric machine, and the insulation between the conductors and the conductor bundle for the slot For applying insulation,
    Aggregated mica paper obtained by mixing and producing hexagonal boron nitride powder having a crystallization index of 1.8 or more, a woven fabric made of at least one of inorganic and organic materials, and a high adhesive strength for bonding the aggregate mica paper and the woven fabric. A coil insulator for a rotating electrical machine obtained by winding a mica tape made of a molecular organic resin around the wire bundle, impregnating the mica tape with a thermosetting polymer organic resin, and curing the mica tape.
  4. 絶縁被覆導線を束ねて導線束を構成し、該導線束を回転電機の回転子鉄心又は固定子鉄心に有するスロット内に配設され、前記導線相互間の絶縁並びに前記スロットに対する導線束を取り巻く主絶縁を施こすためのものであって、
    剥がしマイカあるいは集成マイカの少なくとも一つから構成されるマイカ層と、無機物あるいは有機物の少なくともいずれか一つからなる織布と、前記マイカ層と織布を接着する半硬化した熱硬化性の高分子有機樹脂からなるマイカテープを、前記織布と対向する面あるいはマイカ層と対向する面の少なくとも一方に、少なくとも結晶化指数が1.8以上の六方晶窒化ホウ素の粉体を含む有機樹脂で塗布したマイカテープで、前記導線束に巻回した後、加圧成形し、かつ加熱硬化して得られる回転電機のコイル絶縁物。
    A conductor bundle is formed by bundling insulation-coated conductors, and the conductor bundle is disposed in a slot having the rotor core or stator core of the rotating electric machine, and the insulation between the conductors and the conductor bundle for the slot For applying insulation,
    A mica layer composed of at least one of peeled mica or laminated mica, a woven fabric composed of at least one of an inorganic material and an organic material, and a semi-cured thermosetting polymer that bonds the mica layer and the woven fabric A mica tape made of an organic resin is coated with an organic resin containing hexagonal boron nitride powder having a crystallization index of 1.8 or more on at least one of the surface facing the woven fabric or the surface facing the mica layer. A coil insulator for a rotating electrical machine obtained by winding the conductive wire bundle with a mica tape, press-molding, and heat-curing.
  5. 絶縁被覆導線を束ねて導線束を構成し、該導線束を回転電機の回転子鉄心又は固定子鉄心に有するスロット内に配設され、前記導線相互間の絶縁並びに前記スロットに対する導線束を取り巻く主絶縁を施こすためのものであって、
    結晶化指数が1.8以上の六方晶窒化ホウ素の粉体を混抄、抄造した集成マイカと、無機物あるいは有機物の少なくともいずれか一つからなる織布と、前記集成マイカと織布を接着する半硬化した熱硬化性の高分子有機樹脂からなるマイカテープを、前記導線束に巻回した後、加圧成形・加熱硬化して得られる回転電機のコイル絶縁物。
    A conductor bundle is formed by bundling insulation-coated conductors, and the conductor bundle is disposed in a slot having the rotor core or stator core of the rotating electric machine, and the insulation between the conductors and the conductor bundle for the slot For applying insulation,
    Aggregated mica obtained by mixing and pulverizing hexagonal boron nitride powder having a crystallization index of 1.8 or more, a woven fabric made of at least one of an inorganic material and an organic material, and a semi-bonding material for bonding the assembled mica and the woven fabric. A coil insulator for a rotating electrical machine obtained by winding a mica tape made of a cured thermosetting polymer organic resin around the wire bundle, followed by pressure molding and heat curing.
  6. 前記結晶化指数(GI)は、X線回折像において、窒化ホウ素の(100)面、(101)面、(102)面のピーク面積を用いて(1)式で表される値GI(graphtization index)である請求項1〜5のいずれかに記載の回転電機のコイル絶縁物。
    GI=(S(100)+S(101))/S(102) …(1)式
    ここで、S(100)は(100)面のピーク面積を示す。
    The crystallization index (GI) is a value GI (graphtization) expressed by the equation (1) using the peak areas of the (100) plane, (101) plane, and (102) plane of boron nitride in an X-ray diffraction image. 6) The coil insulator for a rotating electrical machine according to any one of claims 1 to 5.
    GI = (S (100) + S (101)) / S (102) (1) formula
    Here, S (100) represents the peak area of the (100) plane.
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